Back to EveryPatent.com
| United States Patent |
5,685,116
|
|
Bradshaw
, et al.
|
November 11, 1997
|
Preshaped form
Abstract
A system of prefabricated plaster relief forms are manufactured to be
applied to prepared walls of a building, such as a home or other
structure. The prefabricated forms are made of an open work lattice
material formed into a channel shape having a top, two depending sides and
outward directed flange portions. The lattice material is configured to
receive and hold a cementitious material such as plaster. The top and the
sides of the prefabricated forms are configured to present a protuberant
contour projecting away from the flange sections and thereby outwardly
from the prepared wall. The cross section and the ends of the
prefabricated forms are shaped to align end-to-end with identically shaped
forms. Alignment of a plurality of such forms in a longitudinal direction
provides a continuous relief band along the wall of a structure. The
prefabricated relief form flange sections are configured for attaching to
the prepared walls by means of nails, screws or adhesive. An alternative
prefabricated form member includes one or more guide members oriented in
the longitudinal direction and spaced apart from the top and the sides.
The guide member provides a guide edge for guiding a plastering tool along
the length of the form while the form is being coated with plaster.
Alternative angled prefabricated forms are provided for joining with
adjacent longitudinal forms to create continuous relief bands around the
corners of intersecting walls or the corners of door and window openings.
| Inventors:
|
Bradshaw; James H. (Pismo Beach, CA);
Rodlin; Daniel W. (Oceano, CA);
Myrick; Randall T. (Grover Beach, CA)
|
| Assignee:
|
John Cravens Plastering, Inc. (Santa Maria, CA)
|
| Appl. No.:
|
441251 |
| Filed:
|
May 15, 1995 |
| Current U.S. Class: |
52/311.1; 52/255; 52/344; 52/443; 52/454; 52/717.06; 52/799.11 |
| Intern'l Class: |
E04C 005/01; 800.1; 800.11; 800.12; 255-257; 454 |
| Field of Search: |
52/311.1,311.3,316,344,350,364,443,450,717.06,730.1,730.2,798.1,799.1,799.11
|
References Cited
U.S. Patent Documents
| 279011 | Jun., 1883 | Phelps | 52/DIG.
|
| 945656 | Jan., 1910 | White | 52/670.
|
| 1147000 | Jul., 1915 | Burk | 52/671.
|
| 1309242 | Jul., 1919 | Clark | 52/649.
|
| 2012203 | Aug., 1935 | Peterson | 52/255.
|
| 2045482 | Jun., 1936 | Maier | 52/316.
|
| 3333379 | Aug., 1967 | Harris | 52/364.
|
| 3391509 | Jul., 1968 | Fruman | 52/255.
|
| 3426490 | Feb., 1969 | Taylor.
| |
| 3462900 | Aug., 1969 | Morrissey.
| |
| 3679529 | Jul., 1972 | Prusinski et al.
| |
| 3815308 | Jun., 1974 | Corey.
| |
| 3932973 | Jan., 1976 | Moore.
| |
| 3944161 | Mar., 1976 | Kauf.
| |
| 3974612 | Aug., 1976 | Karner.
| |
| 3977149 | Aug., 1976 | Haynes et al.
| |
| 4094110 | Jun., 1978 | Dickens.
| |
| 4154039 | May., 1979 | Debeuckelaere.
| |
| 4288954 | Sep., 1981 | O'Donnell.
| |
| 4341050 | Jul., 1982 | Long.
| |
| 4539247 | Sep., 1985 | Andersson.
| |
| 4763455 | Aug., 1988 | Schneller | 52/255.
|
| 4796393 | Jan., 1989 | Toti.
| |
| 4923733 | May., 1990 | Herbst.
| |
| 5029424 | Jul., 1991 | Hingos.
| |
| 5103601 | Apr., 1992 | Hunt | 52/12.
|
Other References
AMICO-WEST, Metal Lath Building Products, 9 Pages Catalog. Jun. 1988.
Cemco Metal Lath & Accessories 10 Page Catalog # 3403 P.
|
Primary Examiner: Canfield; Robert
Attorney, Agent or Firm: Steres; George M.
Parent Case Text
This is a continuation of application of Ser. No. 08/222,826 filed Apr. 5,
1994 now abandoned.
Claims
What is claimed is:
1. A prefabricated relief form member for receiving and retaining a fluid
cementitious coating when the form member is attached to a prepared
structural wall, the member comprising:
a longitudinal channel presenting a protuberant surface defining a
predetermined lateral contour between two opposed mounting flanges;
the flanges adapted for mounting to the prepared structural wall;
the surface having a plurality of apertures therethrough adapted to receive
and retain the coating;
the surface defining at least one longitudinal line parallel to and
extending the length of the channel;
the channel surface comprised of expanded, galvanized metal having a
preformed weight of about 3.4 pounds per square yard;
at least one edge guide parallel to and spaced apart a preselected distance
from the at least one longitudinal line, the edge guide configured to
provide a guide edge for a tool;
connecting means for rigidly connecting the edge guide in spaced apart
relationship to the channel surface;
whereby the edge guide provides a secure guide edge for a tool used to
apply the cementitious coating to a preselected thickness along the length
of the member.
2. A member as set forth in claim 1 wherein:
the channel surface is formed having an array of elongated hexagons, the
hexagons having a major axis of about 1/2 inch and a minor axis of about
3/8 inch, adjacent hexagons along the minor axis being connected at
opposed sides by respective common side segments of about 1/8 inch in
length, adjacent hexagons along the major axis being connected at the ends
of respective 3/8 inch common end segments, the respective side and end
segments connected by corresponding right and left angled linking
segments.
3. A prefabricated relief form member for receiving and retaining a fluid
cementitious coating when the form member is attached to a prepared
structural wall, the member comprising:
two opposed mounting flanges adapted for mounting to the prepared
structural wall;
a longitudinal channel presenting a protuberant surface connecting between
the opposed mounting flanges, the surface defining a predetermined lateral
contour, a substantial portion of the surface spaced substantially away
from and between the two opposed mounting flanges;
the surface having a plurality of apertures therethrough adapted to receive
and retain the coating;
the surface defining at least one longitudinal line parallel to and
extending the length of the channel, wherein the channel surface comprises
metal strands of about 0.020 inches thick;
at least one edge guide integrally formed parallel to and spaced apart a
preselected distance from the at least one longitudinal line, the edge
fluid configured to provide a fluid edge for a tool;
connecting means for rigidly connecting the edge guide in spaced apart
relationship to the channel surface;
the member being non-flammable and non-permeable to water,
whereby the edge fluid provides a secure fluid edge for a tool used to
apply the cementitious coating to a preselected thickness along the length
of the member.
4. A prefabricated relief form member for receiving and retaining a fluid
cementitious coating when the form member is attached to a prepared
structural wall, the member comprising:
two opposed mounting flanges adapted for mounting to the prepared
structural wall;
a longitudinal channel presenting a protuberant surface connecting between
the opposed mounting flanges, the surface defining a predetermined lateral
contour, a substantial portion of the surface spaced substantially away
from and between the two opposed mounting flanges;
the surface having a plurality of apertures therethrough adapted to receive
and retain the coating;
the surface defining at least one longitudinally line parallel to and
extending the length of the channel;
at least one edge guide integrally formed parallel to and spaced apart a
preselected distance from the at least one longitudinal line, the edge
guide configured to provide a guide edge for a tool;
connecting means for frigidly connecting the edge guide in spaced apart
relationship to the channel surface, wherein the connecting means
comprises a plurality of wire support members;
the member being non-flammable and non-permeable to water;
whereby the edge guide provides a secure guide edge for a tool used to
apply the cementitious coating to a preselected thickness along the length
of the member.
5. A member as set forth in claim 4 wherein the plurality of wire support
members are connected between the channel surface and the edge guide by a
process selected from the group of gluing and spot welding.
6. A prefabricated relief form member for receiving and retaining a fluid
cementitious coating when the form member is attached to a prepared
structural wall, the member comprising:
mounting means for attaching the member to the prepared structural wall;
a protuberant surface defining a predetermined lateral contour, the surface
spaced substantially away from the mounting means and supported by the
mounting means;
at least one edge guide adjacent to and spaced apart a preselected distance
from the protuberant surface, the edge guide configured to provide a guide
edge for a tool;
connecting means for rigidly connecting the edge guide in the spaced apart
relationship to the protuberant surface;
the member being non-flammable and non-permeable to water; wherein the
protuberant surface includes a plurality of apertures therethrough adapted
to receive and retain the cementitious coating;
the member including a backing to limit the amount of cementitious material
received and retained by the apertures of the member,
whereby the edge guide provides a secure guide edge for a tool used to
apply the cementitious coating to a preselected thickness on the
protuberant surface.
7. A member as set forth in claim 6 in which the backing is a layer of
paper attached by an adhesive between the paper and the member.
8. A member as set forth in claim 7 in which the paper is a moisture proof
asphalt saturated paper.
9. A prefabricated relief form member for receiving and retaining a fluid
cementitious coating when the form member is attached to a prepared
structural wall, the member comprising:
two opposed mounting flanges adapted for mounting to the prepared
structural wall;
a longitudinal channel presenting a protuberant surface connecting between
the opposed mounting flanges, the surface defining a predetermined lateral
contour, a substantial portion of the surface spaced substantially away
from and between the two opposed mounting flanges;
the surface having a plurality of apertures therethrough adapted to receive
and retain the coating;
the surface defining at least one longitudinal line parallel to and
extending the length of the channel;
at least one edge guide integrally formed parallel to and spaced apart a
preselected distance from the at least one longitudinal line, the edge
guide configured to provide a guide edge for a tool;
connecting means for rigidly connecting the edge guide in spaced apart
relationship to the channel surface;
the member being non-flammable and non-permeable to water;
the member including a backing to limit the amount of cementitious material
received and retained by the apertures of the member, whereby the edge
guide provides a secure guide edge for a tool used to apply the
cementitious coating to a preselected thickness along the length of the
member.
10. A member as set forth in claim 9 in which the backing is a layer of
paper attached by an adhesive between the paper and the member.
11. A member as set forth in claim 9 in which the paper is a moisture proof
asphalt saturated paper.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to prefabricated, light-weight, plaster relief forms
to provide quick, low cost, installation of support members for
constructing plaster coated decorative "plant-on's" or "bump-outs" to the
outside walls of dwelling structures.
2. Previous Art
Ornamentation and decoration of building structures such as residences and
businesses is one important aspect of architecture. Marketing and sale of
residences is enhanced by additional decorative detail. Pride of ownership
is also enhanced by improved appearance of one's building or residence.
Ornamentation and decorative details are used extensively to add
desirability and attractiveness to structures.
In certain regions of the country, such as the West and Southwest, the
homes in the Mission style, and the Mediterranean style are quite popular.
One of the popular methods of ornamentation used for these styles of homes
is referred to in the building trades as "plant-ons" or "bump-outs". The
plant-ons may extend for a considerable length along the horizontal or
vertical dimension of a wall or walls of a home or business. The plant-ons
add a band or bands of relief to an otherwise blank facade that is
presented by an unbroken expanse of plaster or stucco. The bands may
extend completely around the outside perimeter of a building. For a
conventional home of 2500 sq. ft., this may amount to 300-500 ft of bands
for one single layer. The support for these bands are generally made of
overlapping wooden boards including a first layer of 2.times.12 inches and
a second layer of 2.times.8 inches. The boards are placed end to end in
standard lengths of 8 to 12 ft to create a continuous relief band around
the home. Similar bands may be constructed around door and window
openings.
Attractive relief borders around windows and doors are also used to provide
enhancements to the architecture of homes and buildings. Such window and
door borders have been constructed using the above methods and materials.
These features are not necessary to the structural integrity of the
building, but do add a pleasing visual aesthetic appearance to a home or
business.
One example of architectural relief products for attachment to homes are
pre-shaped foam members such as cornices, bases, sills and balusters, for
example, supplied by High Tech Foam Products, Inc of Corona, Calif. Foam
members may be provided in a wide variety of shapes and sizes. The
disadvantage of these members as supports for relief bands include the
expense of the items themselves, on the order of $5 to $6 per linear foot,
and the additional labor and material involved in adding a layer of
screening or lath material over the foam to provide a matrix for the
plaster to adhere.
A conventional method of construction of plant-ons uses one or more planks
of overlapping boards attached to a wall at a particular height. To
achieve a continuous band or strip of relief, multiple lengths of uniform
cross section boards are aligned end to end and attached to the studs of a
prepared wall. For conventional construction, the studs must be no more
than 24 inches on center, or less, according to the applicable local,
state or national building codes. The attachment is done with hammer
driven nails, power gun driven nails, large staple guns or the like. The
boards are attached to the wall prior to the application of a plaster coat
or coats and prior to the application of a lath sheeting which will form a
matrix or lattice for supporting the plaster when it is applied. The lath
is conventionally made of chicken wire or expanded metal and attached with
nails, staples or the like. The lath sheeting may be suspended away from
the wall and boards by a furring strip or strips interposed between the
surface of the wall and the sheeting. Self furred sheeting or wire may
also be used to maintain the spacing between the wall and the sheeting. An
example of such wire is self furred metal lath made by California Expanded
Metal Products Company of Industry, Calif. "Dimpled" or ribbed type self
furring metal lath provides a 1/4 inch indentation in the metal lath to
hold it away from the wall allowing the plaster to fill the space between,
insuring the lath is embedded. The spacing between the lath and the wall
or boards provides the opening for the plaster coat to surround the lath
and thereby bond firmly to the wall. A moisture barrier layer, of building
paper, for example, is applied between the boards and the lath sheeting by
means of staples, nails, an adhesive coating or the like.
The boards provide the relief pattern or bump-out desired. Additional
screening is cut and shaped by hand to conform to the protruding bump-out
and nailed or stapled to the boards and the wall.
Plaster is then applied to the bump-out and the wall to form the finished
surface.
With reference to FIG. 10A, there is shown a schematic diagram of an
exploded view of one previous art method of assembly for a manually
fabricated plaster relief form as described above. A plurality of boards
of desired width with the same cross section are aligned end to end and
nailed to the prepared wall to form a continuous plaster relief band to
the desired length. Additional lengths of wire screen or lath sections may
be placed over the boards and formed by hand to the contour of the boards.
The additional sections are then typically nailed in place. FIG. 10B
illustrates a cross section of such a relief form having a board attached
to a stud framed wall. A layer of moisture barrier paper and metal screen
or lath are typically placed against the wall and attached by nails to the
studs. A plurality of spacers, such as furring strips or dimples in the
additional screen sections, are provided between the boards and the
additional wire screen sections to allow the subsequent plaster layer to
flow into the openings of the wire screen sections and fill the space
between the screens and the top of the boards. Plaster is then typically
applied by hand using a hawk and trowel method or applied with a nozzle
connected to a machine as described above.
With reference to FIG. 10C, an additional improvement to the previous art
method is shown. Guide edge members are attached, typically by nailing
into the form boards, to the edges of the wire screen sections over the
plaster form boards. The guide edges are spaced apart from and aligned to
be parallel with the plaster form boards. The guide edge members provide a
guide to the trowel or plaster dispensing nozzle as the plaster is
applied, thereby allowing a uniform depth of plaster to be applied easily.
Representative guide edge members used in the trade are made from 14 gauge
wire such as the "CEMCORNER" corner reinforcement made by Cemco, Covina
Lane, Calif. or the "CornerAid" cover nose wire made by Stockton Products,
Burbank, Calif.
The above described method requires a number of hand operations, such as
nailing the boards, cutting the additional wire screen sections, hand
forming the screen sections over the boards and attaching the guide edge
members, which significantly increases the cost of applying plaster relief
bands. It would be an advantage to provide a system to reduce the number
of hand operations required to apply plaster relief bands.
It is important to select boards made of wood which are of uniform cross
section, in order to achieve a visually pleasing effect. Boards which are
not uniform in thickness or width will show angular offsets at the ends
where they meet. It is also important to select wood which is well cured
and has stable dimensional shape. If the wood twists or otherwise deforms
after the plaster has dried, unsightly cracks may appear. Cracks may also
allow moisture to penetrate the plaster and attack the wood beneath, or
provide additional unwanted access to wood destroying pests. Boards of
suitable quality currently sell for $2 to $3 per linear foot. On a double
band board structure, the cost could be from $15 to $18 per linear foot,
after including the costs of boards, lath application and finished
plaster.
The use of wood for forming the support structure for the plaster of
decorative bands is well known in the trade. As the costs of wood continue
to increase, and the availability of high quality boards continues to
diminish, there is an urgent need to provide an alternative low cost
structure which will satisfy the desire for aesthetic enhancements to the
various stucco and plaster styles of home and office.
The non-uniformity of wooden boards in width and thickness can cause
unsightly mismatch in the appearance of the relief bands on a home. Either
higher quality and thus higher cost boards must be purchased, or labor
intensive and expensive modification must be made on the job site. This
slows down the assembly process and further adds to the cost of building.
It would be an advantage to provide a support structure for plaster relief
bands which would guarantee uniformity in cross section aspect and thus
match precisely when aligned at the ends.
The weight of the wood used for the band support structure creates several
concerns. Handling and aligning long lengths of boards takes considerable
strength and capability. Moving and holding a 12 foot length of board may
require two workers to align successive boards. The cost of shipping the
wood used in making the band supports is also a factor in the cost of
building plaster or stucco homes. Wood often is shipped in a condition
wherein it contains an appreciable amount of water which significantly
increases the weight of the wood. Wood typically contains 30% or more
water by weight. Such additional weight is of no use and in fact may be
harmful as described above. Wood used for decorative support may also be
stored outdoors while awaiting construction. It is possible for the wood
to absorb moisture from the surroundings thereby increasing its weight
even if it had been shipped in an originally dry state. It would be an
advantage to have a band support structure which is lighter in weight,
thereby reducing the cost and time of installation and the cost of
shipping to the job site. It would be an additional advantage to provide a
band support structure which could not absorb water while stored at a
building site.
The use of wood as a building material combined with increased demands from
a growing population puts increasing pressure on our forest preserves. It
would be an advantage to provide a substitute material which would reduce
the need to use wood except where it is most effective, thereby preserving
our valuable resources.
Even though the wood for plant on bands is covered by fire-resistant
plaster, the building codes still require the bands to be considered
flammable structures. It would be an advantage to provide a substitute
material which was impervious to fire, and thereby add increased safety to
homes and buildings.
SUMMARY OF THE INVENTION
The general purpose of the invention is to provide light weight, low cost
prefabricated plaster relief form members which can be shipped to a
construction job site in final form to simplify the application of relief
bands to the exterior of homes and buildings which are to be coated with a
cementitious coating, typically plaster or stucco.
According to one embodiment of the invention a prefabricated plaster relief
form member is provided for receiving and retaining a fluid cementitious
coating, such as plaster, when the member is attached to a prepared
structural wall.
The member is configured from an openwork lattice sheet, preferably of an
expanded metal lath. The lattice sheet is adapted to receive and retain
the plaster when the plaster is applied by hand or by spraying with a
nozzle of a machine. The lattice sheet is formed into a longitudinal
channel having a top with opposed outer edges.
Two spaced apart sides extend away from the respective opposed outer edges,
to respective base edges. The respective base edges are aligned parallel
to the top such that a mounting plane is defined parallel to the top of
the channel.
Two mounting flange portions, each extending outward and away from the base
edges of the respective sides, lie within the plane parallel to the
channel.
The member is thus defined as a channel having a length between two opposed
ends and a width between the two opposed sides. The channel is configured
to have an essentially uniform lateral cross section, perpendicular to the
longitudinal dimension, protruding away from the mounting plane.
The flange sections are adapted for mounting to the prepared structural
wall such that a plurality of such members mounted on the structural wall
and adjoined end-to-end form a continuous relief band protruding from the
wall. The flange sections may be nailed or stapled to the studs of a
prepared wall after adjacent form members are aligned and adjoined
end-to-end.
The regular cross section of similar prefabricated form members ensures an
aesthetically pleasing effect is easily achieved without shaving, trimming
or selecting wooden boards.
The light weight and regular shape of these prefabricated members enable
for easy and low cost installation of the support forms needed for
applying relief bands to stucco homes and buildings.
The metal lath or lattice work is light, but has sufficient strength to
support the plaster coating and hold it in place while it cures. The
prefabricated shape enables the construction of plaster relief bands
without the use of wood boards and the additional weight and shipping cost
involved. The cells and strands of the lattice work provides openings for
the plaster to flow and provides a secure network for the plaster to take
hold while it hardens.
The uniform shape of the form member is dimensionally stable and not
subject to absorbing water. This eliminates the potential of warping that
occurs with the use of wood as support members for relief bands.
The combination of the structural support and the open lattice in the one
element of the prefabricated form member reduces the labor that otherwise
is involved in attaching sheets of screen wire to the wood planks used in
conventional construction.
In another embodiment of the prefabricated form member, there is provided
at least one edge guide segment parallel to and spaced apart a preselected
distance from at least one of the channel outer edges. The edge guide
segment is aligned parallel to the length of the member and is configured
to provide a guide edge for a tool. A connecting frame is provided for
rigidly connecting the edge guide segment to the member such that the edge
guide segment provides a secure guide edge for a tool used to apply the
plaster or stucco coating to a preselected thickness along the length of
the member. A preferred thickness of plaster coating is about 7/8 inch
minimum in the finished state.
The prefabricated form member is typically formed from expanded, galvanized
metal having a preformed weight of about 3.4 pounds per square yard. The
lattice is shaped into an array of elongated hexagons, the hexagons having
a major axis of about 1/2 inch and a minor axis of about 3/8 inch. The
adjacent hexagons along the minor axis being connected at opposed sides by
respective common side segments of about 1/8 inch in length, and adjacent
hexagons along the major axis being connected at the ends of respective
3/8 inch common end segments, while the respective side and end segments
are connected by corresponding right and left angled linking segments.
A prefabricated form member as described above is non-permeable to water,
non-flammable and semi-rigid and has a lateral strength sufficient to
support a plaster coating having a thickness from about 1/2 inch in
thickness, to about 2 inches in thickness;
It is an advantage in accordance with this invention to provide plaster
relief form members which eliminate the use of lumber in achieving
architectural enhancement effects.
It is a further advantage in accordance with this invention to provide
plaster relief form members which reduce the cost of installation.
It is a further advantage in accordance with this invention to provide
plaster relief form members which are lower in weight than equivalent
lumber elements.
It is a further advantage in accordance with this invention to provide
plaster relief form members which reduce the cost of shipping members to
the job site.
It is a further advantage in accordance with this invention to provide
plaster relief form members which are uniform in cross section and
impervious to warping or cracking.
It is a further advantage in accordance with this invention to provide
plaster relief form members which reduce the number of hand operations and
thereby reduce the cost of installation.
It is a further advantage in accordance with this invention to provide
plaster relief form members which are non-flammable.
It is a further advantage in accordance with this invention to provide
plaster relief form members which may be mass produced in a wide variety
of standard shapes at low cost.
It is a further advantage in accordance with this invention to provide
plaster relief form members which can be easily joined end-to-end to form
visually uniform relief bands on outer walls, around door or window
openings and along the facia of a building. The relief bands have stable
shape with age and are resistant to warping and cracking due to moisture
absorption/desorption.
BRIEF DESCRIPTION OF THE DRAWINGS
For a further understanding of the objects and advantages of the present
invention, reference should be had to the following detailed description,
taken in conjunction with the accompanying drawings, in which like parts
are given like reference numerals and wherein;
FIG. 1 is an exploded perspective view of prefabricated plaster relief
forms members aligned end to end in accordance with this invention.
FIG. 2 is a plan view of a section of expanded metal lath used as the open
work lattice material to make a preformed plaster relief form member in
accordance with this invention.
FIG. 3 is a perspective view of an alternative prefabricated plaster relief
form member having a paper backing.
FIG. 4 is a perspective view of an alternative prefabricated plaster relief
form member angled to fit around intersecting walls.
FIG. 5 is a perspective view of an alternative prefabricated plaster relief
form member angled to fit around door or window casings.
FIG. 6 is a perspective view of one corner a prefabricated plaster relief
form member having a prefabricated guide edge member in accordance with
this invention.
FIG. 7 is a cross section taken along viewing plane 7--7 of FIG. 6.
FIGS. 8a and 8b are cross sections of two alternative plaster relief form
members in accordance with this invention.
FIG. 9 is an exploded perspective view of two plaster relief form members
aligned end-to-end on a structural wall.
FIG. 10A is a perspective view of a previous art method of attaching hand
made plaster relief forms made of wood and wire screen.
FIG. 10B is a cross section of a previous art hand made plaster relief
form.
FIG. 10C is a cross section of a previous art hand made plaster relief form
having separate guide edge members manually attached.
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION
With reference to FIG. 1, there is shown an embodiment of the prefabricated
plaster relief form member in accordance with this invention, generally
referred to by the numeral 20. The member 20 is shown aligned end-to-end
with similar members 20a and 20b. The member 20 is formed from an open
lattice material 22 such as 3.4 lb/sq. yd. diamond mesh expanded metal
made by Western Metal Lath Company of San Leandro, Calif. The lattice
material 22 is bent on a tool such as a sheet metal brake in a metal shop
to form a longitudinal channel having a protuberant contour 30 with a top
surface 31, opposed sides 34, 36 at essentially right angles to surface
31, and opposed ends 38, 40. The sides 34, 36 of lattice material 22 are
bent to form flanges 42, 44 extending at essentially right angles away
from the respective sides 34, 36 of the member 20. The flanges 42, 44 are
configured to lie in the same mounting plane 46 indicated by the arrows x,
y. The mounting plane 46 and flanges 42, 44 are essentially parallel to
the length L of the member 20. The depth D of the member 20 is typically
about 11/2 inches, the width W typically about 6 to 12 inches and the
length L typically 6 to 10 feet. The flanges 42, 44 extend a distance F
typically about 11/2 inches respectively from each side 34, 35. The member
20 is configured so that each end 38, 40 can abut contiguously at each end
38, 40 with adjacent identical members, as indicated by members 20a and
20b, to form a continuous relief band when mounted on a prepared
structural wall. The application and method of use of prefabricated
plaster relief bands is described below.
The members 20, 20a, 20b would typically be fabricated at a remote site,
such as a metal shop or manufacturing plant by using tools well known in
the metal working trade.
A preferred manufacturing method for the prefabricated members 20 is an
automated means such as high speed punches and presses operated with
appropriately configured molds to achieve a desired contour. Finished
members 20 would then be shipped to a job site for installation by lower
cost tradespeople.
With reference to FIG. 2, there is shown a detail of a typical lattice
material 22. A preferred lattice 22 is typically formed of galvanized
steel expanded to provide an hexagonal close packed array 48 of cells 50
bounded by strands 52. The strands 52 are formed of galvanized sheet steel
typically about 0.020 inches thick. The cells 50 are elongated hexagons
with major axis 54 about 11/16 inch long and minor axis 56 about 5/16 inch
wide. Alternatively, the lattice 22 may be formed of lighter or heavier
expanded metal, such as 1.75 lb/sq. yd or 2.5 lb/sq. yd. for smaller or
larger preformed members. A suitable material is the galvanized steel
diamond mesh of 3.4 Ib/sq.yd. made by Western Metal Lath Co. La Mirada,
Calif.
With reference to FIG. 3, an alternative embodiment of a prefabricated
plaster support member in accordance with this invention is shown. A paper
backed lattice material may be used to make a member generally indicated
by numeral 60. An example of such a paper backed lattice material is
"CEM-LATH K" made by Cemco, of Industry, Calif. "CEM-LATH K" is a 3.4
lb/sq. yd. diamond mesh metal lath 62 backed with asphalt saturated
"Kraft" paper 64 which may be used to form a plaster support member 60 in
accordance with this invention. The paper backing 64 may be used to limit
the amount of plaster which is needed to cover the member 60 after the
member 60 is applied to a prepared structural wall (not shown).
The paper 64 extends a suitable distance such as 11/2 to 2 inches beyond
the flanges 42, 44 and ends 38, 40 of the metal lath 62. The paper 64
extension provides an overlap with adjacent paper backed members (not
shown), when aligned end to end, to ensure a continuous moisture barrier
which may be required by local or state building codes.
It is contemplated that the paper 64 may be applied to the back of the lath
62 before forming the member 60. Application of the paper 64 to the back
of the lath 62 may be made by adhesive means 63 such as a hot glue (not
shown) between the paper 64 and the lath 62. The paper 64 and the lath 62
may then be positioned between an upper mold and a lower mold having a
desired shape (not shown). Application of sufficient pressure between the
upper mold and lower mold will cause the lath 62 and paper 64 combination
to be shaped into the desired member 60.
Other preformed shapes for prefabricated plaster form members in accordance
with this invention are contemplated. With reference to FIGS. 4 there is
shown an embodiment of a prefabricated angled member 80. The angled member
80 provides a means to fit a continuous relief band around the corner of a
building (not shown) with out cutting and fitting straight members. The
member 80 is made from open work lattice material as described above. The
member 80 includes a first portion 82 and a second portion 84 joined at a
common edge 86. The portions 82 and 84 may be joined by suitable means
such as spot-welding, hot gluing or wire tying, as is well known in the
trade. The portion 82 and portion 84 are indicated at right angles to each
other, but can be any desired angle to accommodate intersecting structural
walls at other than 90 degree angles. The portions 82, 84 are configured
to have similar protuberant cross sections and protrude in a direction
normal to the respective intersecting walls. The portions 82, 84 have
respective lengths L1 and L2 measured from the common edge 86 to
respective ends 38, 40. The portions 82 and 84 have top surfaces 85a, 85b
intersecting at edge 86. The portions 82 and 84 have respective sides 88a,
88b, and 90a, 90b between the respective walls and respective top surfaces
85a, 85b. Mounting flanges 92a, 92b and 94a, 94b project outward from
respective sides 88a, 88b and 90a, 90b. Flanges 92a, 92b and 94a, 94b are
configured to lie in intersecting mounting planes and are adapted to fit
parallel to the respective adjacent intersecting structural walls.
The member 80 is attached to the studs of a prepared structural wall by
means of nails or staples driven through the respective flanges 92a-94b.
Self-tapping sheet metal screws are typically used to attach the flanges
92a-94b to metal studs. Sharp pointed "Streaker" self-tapping sheet metal
screws available from Pacific Steel and Supply, San Leandro, Calif., may
be used for light gauge metal studs.
The ends 38 and 40 of member 80 are configured as before to abut or overlap
contiguously with respective ends of prefabricated plaster form members
having the same cross section as the member 80. One such abutting
relationship with a plaster form member 20 having the same cross section
as member 80 is indicated by the exploded view of member 20 shown in FIG.
4.
It is often desired to fit the perimeter of door or window openings with
decorative plaster elements. With reference to FIG. 5, another embodiment
of an angled prefabricated plaster form member in accordance with this
invention is shown and generally indicated by numeral 100. In a one
embodiment, the member 100 is made from expanded metal lath as before
described. A first portion 102 is joined with a second portion 104 at a
common edge 106. Portion 102 includes a sheet of expanded metal lath bent
to form spaced apart sides 110a and 110b, a top surface 114 and respective
mounting flanges 116a and 116b. Portion 104 includes a sheet of expanded
metal lath bent to form spaced apart sides 118a and 118b, a top surface
115 and respective mounting flanges 120a and 120b. Portions 102 and 104
are configured to be symmetrical about the common edge 106. The mounting
flanges 116a, 116b, 120a and 120b lie in the same mounting plane indicated
by arrows x, y. Flanges 116a, 116b and 120a, 120b are connected to the
respective top surfaces 114 and 118 by the depending sides 110a, 110b and
118a, 118b. The top surfaces 114, 115 lie in the same plane and are
parallel to the mounting flanges 116a, 116b, 120a, 120b.
ALTERNATIVE PREFORMED PLASTER RELIEF FORM MEMBER
The previous art method of attaching separate guide edge members to the
hand formed plaster relief forms incurs extra handling and additional cost
due to high rate labor charges. With reference to FIG. 6, there is
illustrated a perspective view of a portion of an alternative preformed
plaster relief form in accordance with this invention, and generally
referred to as numeral 150. As before described with reference to FIG. 1,
wherein similar reference numerals are used to designate similar elements,
the member 150 is formed of an open work lattice material 22. A preferred
lattice material is a diamond mesh expanded metal such as 3.4 lb/sq. yd
galvanized metal lath made by CEMCO of Covina Lane, Industry, Calif. The
lattice material 22 of member 150 is preformed to include a top surface 31
having opposed ends 38, 40. The top surface 31 has a bending line along
the surface 31. The bending line is normal to the opposed ends and defines
an edge 33. The lattice material 22 is bent along the edge 33 to define a
side 34 extending downward from the top surface 31. The side 34 extends
downward a suitable distance from the top surface 31, to a second bending
line 35, for example, 11/2 inches. The lattice material 22 is bent along
the second bending line 35, to form a mounting flange 42 extending
laterally outward from the side 34 of the member 150 to a suitable
distance F, e.g. 11/2 inches. A similar bending line, edge, side and
flange (not shown) may be formed in a symmetrical relationship to the side
34 as before described and shown in FIG. 1.
A prefabricated guide edge member 160 is shown in exploded relationship to
the member 150 as member 160 for clarity guide edge member 160 is attached
at a plurality of points 162 along a first edge 164 to the top surface 31
of the member 150. The edge member 160 is attached at a second plurality
of points 66 to the side 34 of member 150. The method of attachment may be
spot welding, or bonding with an adhesive such as hot glue. A preferred
guide edge member 160 is the standard Bullnose regular cover nose wire
having standard 11/2 inch legs made by Stockton Products, Covina, Calif.
The guide member 160 includes a guide edge 168 spaced apart from, and
parallel to, the intersection of the top surface 31 and the side 34. The
guide edge 168 is spaced apart a suitable distance, eg. 5/8, inch from the
top surface 31 of the member 150. The guide edge 168 provides an edge to
guide a tool, such as a trowel, while applying plaster to the member 150,
in such a manner that a uniform plaster coating thickness is easily
achieved on the top surface 31. The guide member 160 includes a plurality
of wire support members 170 and 172 connecting the guide edge 168 and the
respective top 31 and side 34 of the member 150. A similar guide edge 174
spaced apart from the side 34 by a suitable distance, eg. 5/8 inch
provides an edge to guide a tool along the member 150 to achieve a uniform
plaster coating thickness along the side 34.
The exploded view of the member 160' illustrates corresponding attachment
points 162' and 166', the connecting wires 170' and 172' and the guide
edge 168'. The wires 170 and 172 and the attachment points 162, 166
comprise one alternative for a means for support or connecting structure
rigidly supporting or connecting the guide edges 168 and 172 in spaced
apart relationship to the form member surfaces 31 and 34.
With reference to FIG. 7, there is shown in cross section along the viewing
plane indicated by 7--7 of FIG. 6, the contour of the edge guide member
160 attached to the top 31 and the side 34 of the member 150 at attachment
points 162, 166 respectively. The top guide edge 168 and side guide edge
174 are shown as wires attached to the connection wires 170 and 172 and
spaced apart from the top surface 31 and the side 34 by a suitable
distance, typically 5/8 inch.
ALTERNATIVE CROSS SECTIONS FOR PREFABRICATED PLASTER RELIEF FORMS
With reference to FIG. 8a and 8b there are shown alternative cross sections
for prefabricated plaster relief form members in accordance with this
invention. FIG. 8a illustrates a member 200 having opposed sides 202, 203
configured in a stair-stepped shape to provide two layers of relief.
FIG. 8b illustrates a cross section of a prefabricated plaster relief form
member 204 having a stair-stepped aspect with four corner edges 206, 208,
210, 212. Each edge 206-212 has a respective guide edge members 214, 216,
218, 220. Each guide edge member 214-220 provides a top and a side guide
edge 214a,b-220a,b spaced apart from the respective corner edges 206-212
by a suitable distance, eg. 5/8 inch laterally outward and vertically
upward.
With reference to FIG. 9, the use of the prefabricated plaster relief form
is herein described. In use, a structural wall is prepared having a
plurality of studs 180 spaced a suitable distance apart and mounted
vertically along a foundation 182. a layer of asphalted "Kraft" paper 184
for a moisture barrier is applied to the studs 180. A first layer of wire
mesh or screen 186 (commonly called chicken wire) is then attached to the
wall over the paper 184. A line is defined along the wall wherein the
desired decorative architectural structure was to be placed. A plurality
of prefabricated plaster relief form members 200 are aligned end to end
along the line and attached to the wall by means of nails or staples 188
driven through respective mounting flanges 42, 44 into the studs 180. The
light weight but substantially rigid lattice material 22 and uniformity of
shape provided by the preformed members 200 would make the task of
creating a uniform, continuous relief band extremely easy. With reference
again to the detail of FIG. 2, the array 48 of open cells 50 of the
lattice material 22 provides ready access for the application of plaster
to envelop the strands 52 and bond firmly with the lattice 22.
The prefabricated guide edges 160 and 190 of the preformed plaster relief
forms 200 provide guides for guiding a tool to apply plaster to a uniform
thickness along the relief form members 200.
One method of applying a cementitious coating is the well known three step
process. A first coat of cementitious material, typically plaster, called
a scratch coat, would be applied, either by hand trowel or by spraying
from a nozzle connected to a gun feeder, hopper/mixer and pumps as is well
known to those skilled in the art.
One preferred formulation for the scratch coat is set forth in Table 1. It
is within the teachings of this patent to use any other suitable
cementitious material to form the coating for the wall and prefabricated
plaster form 20.
TABLE 1
______________________________________
1 part
Colton Portland Cement type II
3 parts
common coarse sand
5 to 8
gallons of water per sack of cement, depending on the water
content of the sand
______________________________________
The scratch coat covers the wall and the sides and top surface of the form
members 20 to a uniform depth of about 3/8 inch. The scratch coat is cured
for a suitable time, such as 24 to 48 hours, according to the State of
California Uniform Building Code 1988 Edition page 4706, herein
incorporated by reference.
A second coat of plaster about 1/4 to 3/4 inches, with a preferred
thickness or 3/8 inch, called the brown coat, is applied similarly to the
wall and plaster forms 20. The brown coat is cured for a suitable time
such as 7 to 14 days minimum. A suitable formulation for the brown coat is
the same as Table 1, with the addition of a 3 to 5 shovelsful of sand per
sack of cement.
A final plaster coat incorporating the desired color is applied similarly
to a depth of about 1/16 to 1/8 inch. The formulation for the color coat
is typically a mechanically blended compound of portland cement, hydrated
lime and inert aggregates (16/20 or 20/30 sand), such as that supplied by
La Habra Stucco, Anaheim, Calif. Material standards preferably meet
Federal Specification SS-L-351, Type F for hydrated lime, and Type 1 ASTM
C150-56: Federal Specification SS-C192B, for white portland cement.
While the foregoing detailed description has described the embodiments of
the plaster relief form member in accordance with this invention, it is to
be understood that the above description is illustrative only and not
limiting of the disclosed invention. It will be appreciated that it would
be possible to modify the type of lattice material to include larger or
smaller cells and strands, to modify the shape of the cells and the
material, to modify the cross section to include non-uniform shapes, to
add other structures to the plaster relief form member such as flashing
for interfacing with roofing members, to modify the coating of the lattice
material by paint and/or other rust preventative materials or to include
or exclude various elements within the scope and spirit of this invention.
Thus the invention is to be limited only by the claims as set forth below.
Top